Heavy quark potential in quark-gluon Plasma: Deep neural network meets lattice quantum chromodynamics

Abstract

Bottomonium states are key probes for experimental studies of the quark-gluon plasma (QGP) created in high-energy nuclear collisions. Theoretical models of bottomonium productions in high-energy nuclear collisions rely on the in-medium interactions between the bottom and antibottom quarks. The latter can be characterized by the temperature (T) dependent potential, with real (VR(T,r)) and imaginary (VI(T,r)) parts, as a function of the spatial separation (r). Recently, the masses and thermal widths of up to 3S and 2P bottomonium states in QGP were calculated using lattice quantum chromodynamics (LQCD). Starting from these LQCD results and through a novel application of deep neural network, here, we obtain VR(T,r) and VI(T,r) in a model-independent fashion. The temperature dependence of VR(T,r) was found to be very mild between T≈0-334~MeV. For T=151-334~MeV, VI(T,r) shows a rapid increase with T and r, which is much larger than the perturbation-theory-based expectations.